Obduction et collision : exemples de la Nouvelle-Calédonie et de la
géodynamiques qui gouvernent l'obduction et la collision en milieu océanique. De nombreuses variantes de cette hypothèse existent (Dewey et Bird.
Obduction et collision : exemples de la Nouvelle-Calédonie et de la
géodynamiques qui gouvernent l'obduction et la collision en milieu océanique. De nombreuses variantes de cette hypothèse existent (Dewey et Bird.
Superposed structural styles of the Maracaibo basin Venezuela
KEY WORDS: Maracaibo basin structural evolution
Origin of the New Caledonian ophiolites based on a French
Keywords: ophiolites; abduction: seismic profiling; New Caledonia; the junction of the collision zone of the Australian ... Travaux et documents.
Compressive tectonism along the Eastern margin of Malaita Island
oceanic crust from the Ontong Java Plateau obducted over the old Solomon Islands arc during collision between the Pacific and. Australian plates.
Atlas de la Nouvelle Calédonie et dépendances
conseiller les signataires de revoir avec eux ou après eux les documents en cours La présence de ces nappes résulte de l'obduction d'une lithosphère.
Geochemistry and tectonic significance of basalts in the Poya
purposes resale
Compendium of marine species from New Caledonia : second edition
c: document et publi~ par le Service ISe du Ccntre IRD de Noum~a et financé par le post-obduction granitoids of New Caledonia: A ca~e for reactivated ...
1. Actes des Assises de la Recherche Française dans le Pacifique
Jul 7 2000 Deux documents sont fournis à l'issue des ARFP : ... néo-calédonien résulte de processus de collision d'arcs et d'obduction de bassins.
The collision zone between the North dEntrecasteaux ridge and the
tion of a ridge have been poorly documented. An exception is 19811. em termination of the Eocene subdudion/obduction zone.
Third [SAG, St Malo (France), 17-19/9/1996
SUPERPOSED STRUCTURAL STYLES OF THE RlARACAIBO
BASIN, VENEZUELA
Emilio Bueno R.
Maraven, S.A.
Caracas 10 10 A, Venezuela
~~abado 829 KEY WORDS: Maracaibo basin, structural evolution, Caribbean plate collision, Lara nappes obduction,
Eocene foreland basin, superposed tectonics
INTRODUCTION
The Maracaibo basin, which is located between two
andean chains, the Merida Andes and the Sierra de Perija (fig. l), has been subjected to several deforma- tion styles during its geologic evolution. The objective of this paper is the explanation of the different tectonic phases which deformed the sedi- ments of the Maracaibo basin. This structural evolu- tion was constructed from the interpretation of a transect of 2D and 3D seismic lines, which cross the basin from NW to SE (fig. 2).STRUCTURAL FRAMEWORK
The actual Maracaibo basin is located inside a
triangular tectonic block (fig. l), bounded by theBocono fault, in the Merida Andes, the Santa
Marta fault, located west of the Sierra de Perija in Colombia, and the E-W striking Oca fault, running parallel to the boundary with the Caribbean plate.Before the uplift of the Merida Andes, the basin
included theBarinas-Apure basin, located south of the Andes. lnside the triangular tectonic block, one can differentiate two fault systems: a N to NE striking fault
system, which experienced compressional deformation by episodic pulses, and an extensional W to NWstriking fault system. The N to NE striking system consist of two main faults (fig. 3). A lower fault, which
is a thrust propagated at basement and Cretaceous levels and generally absorbed by the Colon shales(Upper Cretaceous). This fault is converted into a drape fold structure at Paleocene levels. The upper fault
is a normal growth fault at the Eocene level and strikes opposite to the overprinted thrustSTRUCTURAL EVOLUTION
During the breakup
of Pangea (Triassic-Jurassic times), the North and South American plates separatedfrom each other forming a belt of rift-grabens (Pindell, 1990), opening the space for the depositional
history of the Maracaibo basin. The graben system extended from the Gulf of Venezuela to the south- 300Third ISAG, St Malo (France), 17-19/9/1996
Schematic NNW-SSE
Transect across the
Maracaibo Basin
reaching Ecuador (Bartok,Reijers and Juhasz, 1981).
The Jurassic La Quinta formation filled the
grabens with volcano-sedimentary sequences. Some of thesegrabens are buried under the thick sediments of the Maracaibo basin and others are outcropping both in
theMerida Andes and the Sierra de Perija
The graben system that developed from extension changed to a compressional phase presumably duringUpper Jurassic to Lower Cretaceous times. Subsequently, the sediments were folded and faulted culminat-
ing in a partial to total erosion (Stephan, 1980).During the Cretaceous
, the sediments were deposited in a passive margin setting (Pindell, 1990) under broad subsidence . After the basal Rio Negro sands thick sequences of the Cogollo group carbonates were deposited (Lower Cretaceous). This was followed by the black bituminous limestones of La Luna forma- tion, which is considered as the main source rock for oil in the basin. The UpperCretaceous was characterized by the
shaly Colon formation, set behind the arch environment (Bartok et al., 1981).Up to the end of Paleocene and during
Eocene the basin area faced an eastward
moving Caribbean plate across its north- em edge. The encounter with this Pacific- derived plate caused two different kinds of events. To the northwestern part of the basin ocurred z collision and subduction.But, the northeastern edge underwent an
obduction. ( Fig 3. E-W Section across the Icotea Structure IThe oblique collision with the Caribbean
plate caused a subduction under the SantaMarta Massive in Colombia, which
Third ISAG, St Malo (France), 17-1 91911 9%
301extended under the Maracaibo basin (van der Hilst, 1993). The resulting compression created a thrust belt in the Sierra de Perija and a foreland tectonic province in the Maracaibo basin. The thrust belt is characterized by faults in a thin-skinned setting, while the foreland area developed basement-involved faults.
In the foreland tectonic province
set in the Maracaibo basin, the compression caused thrust propagation along old N to NE oriented Jurassic grabens and related structures. The thrusts extended across the basement andLower Cretaceous carbonates, but
once reaching the Upper Creta- ceous Colon shales, the reverse faulting detoured and was absorbed. At Paleocene levels, the thrusts were developed into drape fold structures. In the foreland province of the Rocky Mountains in Wyoming, one can observe similar drape fold structures (Lowell. 1985). The resulting high and low areas were filled by Eocene tectono-sedimen- tary sequences and bounded by normal growth faults dipping opposite to the overprinted thrusts. Thecompressional deformation took place though episodic pulses. Each tectono-sedimentary sequence began
with a sediment deposition under extensional regime. After a compressional pulse the sediment wedges
were shortened, slightly folded, inverted and sometimes slightly eroded.A new deposition began once the
compresional pulse ended, began a new deposition. Seismic lines of the Mara field (in the western part of
the basin) defme three different tectono-sedimentary sequences for the Eocene and another three for post-Eocene times (fig. 5).
The compressional Eocene deformation involved only faults striking N to NE, while taking into account
that the main shortening axis was oriented NW-SE (figs. 3 & 4). NFig 4.
Eocene Structural Duality
(Compression /Extension)The extensional deformation was opposite to the compressional forces (fig. 4). As the Caribbean plate
appeared along the northern edge of the Maracaibo basin, its charge produced a flexural deformation, resulting in a foredeep located close to the allochtonous body. The foredeep advanced eastwards together with the Caribbean plate.This event transformed the area of the Maracaibo basin into a foreland basin (Lugo and Mann, 1993). To
accomodate to this new situation, the old sedimentary passive margin platform completed a lithospheric
bend toward the foredeep. In this extensional environment were normal faults striking W to NW, allowing
for a stepweise descent into the foredeep.Towards the central part of the lake (during Lower Eocene times) was located a high, which was presum-
ably a reactivation of the Merida High - active during the Paleozoic. Large normal growth faults bound the northern and southern edges of this high. The eastward migration of the Caribbean plate lead to an obduction. The Lara nappes were pushed over part of the actual Falcon and Lara areas (Stephan, 1977,1980). The foredeep was located close to the obduction zone in the northeastern part of the basin. The combination of NW oriented compression with the eastward foredeep migration which merged withthe Caribbean plate) resulted in a clockwise rotation of the main blocks of the Maracaibo basin. This
action caused sinistral strike-slips along the main faults striking N to NE.Third lSAG, St Malo (France), 17-191911 9%
Evolution (W-E) of Mara Field through
compressional episodic pulses.CONCLUSIONS
The structural styles that have
ocurred in the Maracaibo basin were heavily influenced by plate tectonics. The breakup of Pangea opened the space for Jurassic sediment deposition, followed by a quiet Cretaceous passive margin. Once the Caribbean plate appeared in the northern edge of the area during the Upper Paleocene, the environment changed to a foreland tectonic province. During the Eocene, the obliquecollision with the Caribbean plate in the northwestern edge of the basin (and the following subduction)
produced a NW-SE compression. This caused thrust propagation at the border of old jutrassic grabens. While in the opposite quadrant a foredeep produced by the charge of the allochton and later, by theobduction produced in the northeastern basin edge, gave place to an extensional deformation in a foreland
basin setting. The resulting normal faults strike E-W to NW-SE.Additionally, the combination of the
NW oriented compression with the eastwards foredeep migration(which merged with the Caribbean plate) resulted in a clockwise block rotation. Thus causing sinistral
strike-slips along the main faults striking WE.REFERENCES
Bartok, P., Reijers, T.L.A. and Juhasz, I., 1981:
Lower Cretaceous
Cogollo Group, Maracaibo Basin, Venezuela: Sedimentology, Diagenesis andPetrophysics. Am. Ass. Petrol.
Geol. Bull., v 65p. 11 10 - 11 34.
Lowell, J.D., 1985:
Structural Styles in Petroleum Exploration. OGCI Publications, Tulsa.Lugo, J. and Mann, P., 1993:
Tectonic implications of Paleocene-Eocene foreland basin. Lake Maracaibo, Venezuela. A.A.P.G. Bull.77.331.
Pindell, J.L. and Barret, S.F., 1985:
Geological Evolution of the Caribbean .A Plate-Tectonic Perspective, in:Dengo, G. and Case, J.E., eds.,
The Geology of North America, Boulder, Colorado, p. 405-432.Stephan, J.F., 1977:
El Contacto Cadena Caribe-Andes
Merideiios entre Carora y El Tocuyo (Edo. Lara). Observaciones sobreel estilo y la edad de las deformaciones cenozoicas en el occidente venezolano. V Congreso Venezolano
de Geologia, Caracas, v.2, p. 505-530. Stephan, J.F., Beck, C., Betlizzia, A. et Blanchet, R., 1980:La Chaine Caraibe du Pacifique
A 1'Atlantique. 26th. Geological International Congress. Abstracts C.t. p.38-59.
Van der Hilst, R. and Mann, P., 1993:
Tectonic Implications of Tomographic Images of Subducted Lithosphere beneath Northwestern SouthAmerica.
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